Gas valve structure



Oct. 31, 1944. w. ROBINSON GAS VALVE STRUCTURE Filed March 27, 1941 4 Sheets-Sheet 1 6am Robinson,

Oct. 31, 1944. w ROBlNSON 2,361,655

GAS VALVE STRUCTURE 7 Filed March 27, 1941 4 SheetsSheet 2 lj'r' g. 9.

3 T r' T: 45 0 5 1 3' 49.9

v- 62 6 .929 5a -L V l l F I I l I l I William Rgbinson Oct. 31, 1944. w ROBlNSON GAS VALVE STRUCTURE 4 Sheets-Sheet 5 Filed March 27, 1941 I we nioz,

Zilliarn Rqbjlwp n,

Oct. 31, 1944. w. ROBINSON 2,351,655

GAS VALVE STRUCTURE Filed March 27, 1941 4 Sheets-Sheet 4 na Q 2 pi 2 Patented Oct. 31, 1944 GAS VALVE STRUCTURE Willian iRohinson, Chicago, 1 ll.-, assignor to Certified' Gas Equipment 00., Chicago, Ill.,' acorporation of Illinois Application March 27 1941, Serial No. 385,522 4C1aims. (Cl. 251- 84) Figure l 'is-anaxial sectional'viewon the line l --I of-Figure 2 with the valve element in closed position;

Figure? 211s a'front View of the valve structure; Figure 3 is. a; viewt showing the valvehody element in side elevation and the valve elementarid stem in' axial section on the line 3- 3 of Figure 2,

the valve 'element belng shown in position fora low gas flow;

Figure 4 is-a transverse section'al view orf the line 4-4 .of Figure- 1, the valve -e'lement' being shown in closed position;

' Figures: 5, 6' and 7 are" diagrammatic 'vi'ews showing the valvei-elementxrin" c1'osed,"'ful1 open, and low positions, respectively;

Figure 8 isan axial-section :similar lto'Figure 1, but with the valveelementz-shown in full'sopen position;

:Figure 9 isan axial section ontheline S -9 15f Figure 4;

Figure 10is-a-bottom ViEWOf-ITChB'VB/IVB body element o Figure 8, with the valve .element in axial section on the'line I0--l0 of Figure 8;

Figure 11 is a view ofthe valve =body element looking from the left-with respect to'Figure 8-; Figure 12 is a side elevation of the valve body element of Figure 8;

Figure 13 is a front view of the 'seat face of the Figure 12 valve body element;

Figures 14 and 15 are front and side elevations ofalock element;

Figures 16 and .17 are side andfifrontelevations of the valveelement seating springand-stiopdevice;

Figure 18 is an axial section: of wa modified form of valve structure withawh'a'ndlewindic'ated by dotted lines and the'valve elementsin closed position, but with the stem pressed inwardly 2130 release the lockingldevice;

- Figure 19 is an: elevation of the: Figure 18: structure; the view-looking from the right ofi Figure 18 Figure l'9a is an 'elevation of l a stop element used in the Figure 18'structure;

Figure 'ZO is a transverse sectional viewon =the line 20- 201 of Figure- *18 and with the valve e1ementinclosed-position;

Figure 21 is arr-elevation of the stem shownin Figure 18;

rFigure-22J-is a view similar to Figure-fzlflhut with the-'stem-rot-ated i Figures 23, 24 and 25 diagrammatically 1 show the relation of thevalve element flowports-of Figures- 18 to20 with respectto the valve-body element flow portsin closed; :full open, and low or simmer position;

Figure 26zis an axial section of a valve particularly us'efulin eonneetion'with oven'burners;

Figure 27: is a transverse sectional view entire line 21-21 of Figure 26and-showing the seatface of the valve element;

Figure -'28 :is a transversesectional view on the line 2 8-48 of Figure 26 and showing the outer surface of the valve element;

Figure 29 is a rear view of the valve body element included i in the assemblies I of Figures 18 and 2.6;

Figure-30 is a side'elevation of the valve body element of Figure 29;

Figure 31 is a front elevation showing the Figure 29 valve body element seatface; I

Figure 32-is a rear elevation of a valve body element which may be used' with ovenburners;

Figure 33 is a side elevation, partly in-axial sec tion, of the valvebody element'of Figure 32; and

Figure 34 is a front elevation of the seat face of the valve body) element illustrated in-Figures 32 and 33.

Referring to Figures 1 12017, the numeral -M) designates a valve body element including a. threaded boss 3| through which a supply passage 32 extends, the supply passage being drilled to open to a supply port .33. extendingto the planar seat face-340i the valve-body element. Boss 3l isadapted :to be connected-to agas range manifold.

A boss 35 extends from the rear faoe of' the valve "body-element; boss 35 being drilled to: provide a passage -36 which opens-to a i passage 31 having its outer end-closed -by"a plugf B8,. wJust within the plug 38, a passage 39 extends-' fr-om the seat face-=34 to the hore 3T. @Asuitalfle-adjusting nipple may be threaded upon the outer end of the boss 35 to extend intoithe:air mixing chamber of a gas rangeburner.

As is best shown in 'Figure' 13;. the; supply port 33 and the delivery port' '39 areipositioned from each other on the seat face 34 and a tapered port 39a extends from one side of the delivery port 39 in a clockwise direction (Figures 4 and 13) and generally along a circular line,

The numeral 4| designates the valve element of Figures 1 to 1'? which is hollow and formed of two stamped pieces welded together. Referring to Figures 1 and 4, the seat portion of valve element 4| is a flat disc 42 welded at its periphery to the inner edge of a circular cup-like member 43. The disc or seat member 42 has its seat face 44 flush with the edges of cup member 43, and, as best shown in Figure 4, two ports 45 and 46 are stamped from the disc member, with a tapered tail-port or notch 46a extending from port 46 in a counterclockwise direction (Figure 4) along a generally circular line. As is best indicated in Figure 4, the notch 46a is formed at a point further spaced from the axis of the valve structure than the notch 39a of the valve body element port 39. As a result, when the valve element 4| is in the closed positio-nshown in Figure 4, the two notches will not overlap. In other words, by having the notches spaced at different points from the valve structure axis, they may be of substantial length without necessitating an enlargement of the diameter of the structure.

Cup member 43 has asocket 4'! pressed in the central portion of the same, this socket preferably having one flat side 48 to form a key. In addition, the outer face ofcup member 43 has a number of depressions 49 stamped in the same, three of these depressions preferably being provided equi-distantly spaced about the axis of the valve, element. The socket 41 is preferably of sufilcient depth to contact with the disc 42. Socket .41 thereby braces disc 42 during planar grinding of the latter after welding.

It is found that the use of a disc valve element 4! formed of sheet metal so that it may be hollow is particularly efiicient forv use on a gas valve because it permits the valve element, though of disc form and having the advantages of planar seat faces, to be less than one inch in diameter. It thereby permits the construction of a disc type valve for gas ranges which is of a size commensurate with the usual and less efficient plug type valve.

The ability to make a disc type valve of such small size by the hollow design is particularly due to the fact that ports can be readily stamped in the seat. element 42 and these ports will be joined for flow by the interior of the hollow cup member. Naturally, a channel of this type, that is, one passing through the interior of the valve element and opening at its opposite ends to ports, cannot be formed in a cast metal disc of a thinness comparable to that of the present device, which is slightly less than one-fourth of an inch. Even if the valve element flow passage was simply an open groove in the seat face of a solid element, as is frequently provided in disc valves, such a solid valve element would have to be of greater thickness in order to have flow ports of a comparable size.

A further advantage of the hollow type disc Valve including a disc seat member is that ports of irregular shapes can readily be formed simply by stamping. This is obviously not feasible with a solid metal valve element. That is, whatever grooves or ports are provided in a solid type valve element, either disc or plug, must be formed therein during casting and are not true in outline, and it is not practical to machinethem to proper outline at a low cost.

As is best illustrated in Figures 1 to 8, a sheet metal operating stem may be associated with the hollow valve element 4!, stem 55 being generally of U-shaped form in cross-section with a central circular portion 56 intermediate its ends. In more detail, stem 55 includes an outer end 5'! which is adapted to receive an operatin handle, this portion being arcuate in cross-section or of substatnially U-shaped form with its edges 58 forming a key to engage the operating handle. Portion 58 is inclined inwardly at its inner end to the circular portion 56 which is adapted to rotate within the flange 58 of a casing or plate member 60 secured to the valve body element 30 as hereinafter described, portion 56 thereby serving as the bearing or journal for the stem 55. Inwardly of circular portion 56 stem 5'! is further reduced in size at its inner portion 6| and is again of open arcuate or U-shaped form. The inner portion 6! fits within the central D-shaped socket 41 of the valve element. It will be observed from Figures 9 and 10 that between circular portion 56- and the U-shaped portion 6| of less diameter, a U-shaped or arcuate portion 62 is provided, which portion is of the same diameter as circular portion56, but has its edges lying in the same plane as the reduced diameter and U-shaped portion 6|.

The provision of a stem such as 55 formed of sheet metal so as to be hollow is extremely advantageous due to the low cost at which it may be produced and, in addition, it has the very desirable attribute of permitting cooling of the Valve structure due to the fact that air may flow through the hollow stem to the valve element. This is highly desirable because it insures that any grease used on the seat surface to increase the sealing qualities will not be destroyed by heat.

The inner surface of any handle applied to stem 55 will preferably terminate at the line A in Figure 3 so as to leave an opening between the handle and circular portion 56 for movement of air into and from the housing 60 and the valve element. If the valve housing 60 is covered by a range front cover plate, air can still move through the space described.

In order to hold the valve element 4| closely in engagement with the seat face 34 of valve body element 30, a spring member 65 of the form illustrated in detail in Figure 17 is provided. Member 65 includes a central portion 66 including an aperture 61 with a flattened portion to form a key. Three or more arms 68 are equidistantly spaced about the central portion and extend at an angle to the latter as illustrated in Figurelfi, the ends of these legs being formed in a return bend so as to present a rounded surface. The ends of the arms may also be of greater width than the remainderof the arms. In addition, a tongue 70 extends from the central portion 66, but lies substantially in the same plane as the central portion.

Referring to Figure 1, spring member 65 is fitted upon stem 55 to have its central portion bear upon the inner surface of the forward wall or plate portion of the housing '60.. The aperture 6! of spring member 65 surrounds the portion 62 of the stem; that is, the portion which is immediately outwardly of the smallest and innermost portion 6| of the stem. It will thus be observed that member 65 is concentric with stem 55 and that the Stem may be moved axially oi the housing 60 as hereinafter described without placing any pressure upon .spring member 55 because the portion 62 of the stem will-simply move through .the aperture 61' of the .spring member. Because .of the depth of valve 'disc socket 41, the stem 55 will have adequate engagement therewith and can also move inwardly from the position of Figure l.

The inner and rounded ends of the arms' 58 of spring member 65 seat in the slight depressions 49 on the front face of valve element 4|. In addition, a tongue 10 on the resilient element serves as. a stop member. For example, as. lIIdi', cated in Figure 2, when the valve element 4| is in closed position, tongue 10 bears against a stop lug 15 which projects inwardly from the outer plate or wall of housing 50. the valve element is in its limit open positionas hereinafter described, and which is indicatedin Figures 3 and 7, tongue H1 bears against them- Wardly extending face 16 of an adjustable stop element 11. Stop element 11 includes an arcuate arm 78 which carries aset screw T9 extending through an arcuate cut-out 8|] in the front plate of the housing 50 to enable the stop 11 to be adjusted so as to vary the limit position of the valve element.

Means is also provided with thepresent valve structure to insure that the valve element 4| will be positively locked in off position and that certain intermediate positions Will be indicated by a clicking sound. For this purpose, the looking element 85 illustrated in Figure 14 is mountt ed upon the inner portion SI of stem 55 and is held by a spring 85 in abutment with theshoulder provided at the outer end of such portion by the portion 62 of larger diameter.

As is illustrated in Figure 14, the central portion 87 of lock member 85 has an aperture to fit portion of stem 55 and the aperture includes a flattened portion ,so that it will rotate With the stem. The ends of the radial arms 88 of element 85 are angled to form projecting lugs 89 and the outer edges or surfaces 'of these lugs are fiat. As shown in Figures 2 and 9, when the valve element 4| is in the closed or 01f position, the lugs 89 will extend into rectangular apertures 90 in the front plate of housing 60. As illustrated in Figure 8, when the valve element 4| is in full open position, the ends 'oflock arm portions 89 will engage depressions 9| on the inner surface of housing 60.

The operation of the valve to obtain various flow positions is illustrated in Figures 5 to '7. Referring to Figure 5, the valve element 4| is shown in closed position, its two ports 45 and 46 lying on a line at right angles to the line occupied by the supply port 33 and the delivery port 39 of the body element 30. At this time, the tongue will be against the stop as indicated in Figures 1 and 2 and the lugs 89 of lock element 85 will be seated in the apertures 90 of the housing 60 as shown in Figures 2 and 9. Also, the notches 39a and 45a lie alongside each other, but spaced so that'there can be noflow between them.

Rotation of stem 55 in a clockwise direction from the Figure 5 position will cause'the valve element 4| to rotate on the valve body-element 30 toward the full open position diagrammatically' illustrated in Figure 6. Obviously, rotation may be stopped at a number of points-in ad- Vance of the Figure 6 position to'thereby enable the flow of gas to be varied as desired. When Also, :when

tion,: the ends of the arms-89 of lockmember 85 will engage the depressions 9| of casingztfl as illustrated in Figure 8.

Continued rotation of valve element 4| in; a clockwise .direction will again reduce the flow of gas, and'when element: 4| reaches the posi tion illustrated in Figure "7, the flow of gas will be such as is desirable for simmering. That is, at this time, valve element-port .46; will have moved past valve body elementsup'ply port..3.3 so that-only its notch 46a-=vvill be aligned with the supply port and valve element port '3Wi11 have moved past valve body element delivery port 39 to such .an extent that it will, only be aligned with the tail port 39a. Thus, only a small flow of gas such as used for simmering can occur. At this time; the tongue 10 will engage the adjustable stop H as illustrated in Figure 3.

It will be :observed that the valvelelement 4| cannot be movedHdirect-ly from :the Figure 5 position to that of Figure 'IvWithout :arms 18,9engaging i the depressions 9 l. ment occurs, the person operating thestovemust move the valve stem inwardly to releasethe arms 89 from the depressions so :that the valve will be free to rotate tothe Figure 7 position.

The above arrangement preventing accidental movement :of the valve disc directly item the Figure 5. position ,to, that of Figure. '7 is very desirable as a safety feature. More particularly, mostwgas burner igniting .devicesnecessitate a full flow of gas from the burner before ignition will occur. Therefore, if theoperatorcould move the .valve element Ai-reachestheFigure 6. posi- L15 the valve directly from the off .or Figure 5 :-position to that of Figure 7, gas could then flow from the burnerwithout ignition by tliepilot flame, and in some instances the fact thatithe burner Was not ignited wouldnot be noticed by the operator, as when a large pan is in position on the burner. The continued leakage of gas without ignition of theburner might result in-damage.

Since the present arrangement insures that the rotation of the valve must be stopped -,at least temporarily at the full on position of Figure 6, proper ignition of the burner is ,as-

sured. It will be understood that in order to move the valve element from the closedposition of Figures 2, 5 and 9, very marked inward pressure must be exerted axially on stem 55 to release the lugs 89 from the apertures 90.

It will be noted that the limit or low position of the valve element can be varied by adjustment of the position of the stop 11.

Referring to Figures '18 and 29 to 31, the numeral I00 designates a valve body element including a supply passage H]! which is of angled form and opens to the planarseat face .lfllla through a round port I04 as also shown in Figure 20. Thedelivery port opening todelivery passage I02 has its center on a circular line Which also passes through the center of supply port I04, but passage N32 is inclined inwardly toward the center Of the valve body element H10 so that it may open to a threaded boss Hi3 positioned centrally of the valve body element I00. Supply port llll opens to a threaded boss I05 extending'radially from the periphery ofbody element I00.

A valve element such as-Ma. of Figures-l8, :27 and 28 is mounted upon the valve body element I00. of Figure 18. Valve element 4m includes a round disc 42a which comprises a seat face. Disc 42a is welded at its edges to a'cup-li-ke elelment43a. Element 43a differs from the-element 43 of Figure l, in that it is provided with azcen- When this en agetral aperture in which a separate socket mem'- ber 43b is welded as shown in Figure 18.. This structure is also illustrated in Figure 20, as well as in Figures 26 to 28. The provision of the separate socket member 43b is desirable in forming the valve disc of materials which cannot be drawn to form a socket of sufiicient depth to be properly engaged by the valve operatingstem. Furthermore, a socket of such depth as to contact with the disc element 42a is desirable,'so that the disc and socket can be welded to brace the center portion of the disc. When the disc is thus braced, it can be more easily ground.

Valve element Ma is provided with flow ports III) and I II which, as best shown in Figures 20 and 27, are of sector-like form with their outer edges concentric with the axis of the valve element. However, the two side walls of the ports meet at points spaced radially outward from the axis of the valve and substantially coincidental with the outer surface of the socket member 4%.

groove IIEla, and la, respectively, extending from one edge thereof, as also shown in Figure 2'7, these kerfs facing each other. As best indicated in Figure 20, the kerfs are so positioned that when the valve element Ma is in closed position, the kerfs IIBa and Illa. will lie substantially alongside of the kerfs 165a. and H15?) which extend from opposite sides of the delivery port I of the valve body element I00, due to the fact that the kerfs Ilila and Illa are spaced further from the axis of the valve structure than the kerfs I850. and 1517.

As will be apparent from the following description, the provision of two kerfs on the valve element and two kerfs on the delivery port I85 will enable the valve element to be operated either for clockwise opening movement or counter-clockwise opening movement.

The numeral I40 designates the operating stem of the valve structure of Figures 18 to 25, which stem is preferably formed of sheet metal stamped to a circular shape with the edges of the blank contacting midway of the length of the finished stem as indicated at I4! in Figure 22. Stem I45 has its inner end I42 of sufficiently small diameter to fit within the socket member 432), a cutaway or flattened portion I43 being provided to serve as a key in the D-shaped socket element 4317. Beyond the inner and reduced portion of the stem, there is provided a circular section 144 of larger diameter, thereby providing a shoulder I 44 at the outer end of the inner portion I 42. Beyond portion IM the stem is enlarged to provide a handle receiving portion I45 and the major length of this portion is D-shaped in transverse section due to the fact that its edges Hi5 do not meet. In addition, an indentation M! is provided on the D-shaped portion to assist in holding a handle such as I58 upon the stem. It will be observed that a shoulder I49 is provided by reason of the cut-away edges I56, and this shoulder limits the inward movement of the handle upon the stem as indicated in Figure 18. Due to the fact that the edges I46 are spaced apart as indicated in Figure 22, they may be readily engaged by a proper tool and spread so as to more firmly engage a handle fitted upon the stem.

If desired, an additional cut-out portion as indicated in dotted lines at I59 in Figure 22 may be formed in the shoulder I49, this cut-away portion permitting air to move through the stem to the central portion of the valve disc 4Ia to keep the same cool.

Each of the ports III) and III has a notch or As has been heretofore explained, the portion I42 of stem I40 fits in the socket member 43b of valve element lla. As shown in Figure 18, this portionof the stem also carries a stop member I55 shown in Figure 19a and which includes a radially projecting arm I56, member I55 being in abutment with the shoulder I45 of the stem. A spring 55a is positioned on the stem against stop member I55, spring member 65a being identical in form with the spring member 55 of Figures 16 and 17, except that it does not include a stop arm such as indicated at IS! in these two figures. A look member is positioned on the stem in contact with the spring member 65a, this member being identical with that illustrated in Figures 14 and 15 to include projecting lugs 89, such as illustrated in the last mentioned figures. The elements I55 and 65a may be securely or immovably held upon the stem I45 by fit alone, but, in some instances, it is desirable to strike a tongue I58 from portion I52 of the stem and bend this tongue to the shape shown in Figure 18 so that its free end will engage the spring member 65a to hold the latter and stop member I55 in proper position upon the stem.

It will be noted that the tip of tongue I58 is positioned in anotch 88 (Figure 14) of lock member 85 so that the latter will not be secured against axial movement on stem I40. This will enable the lock member to move toward the valve element against the action of a coil spring 86 pcsitioned between the lock member 85 and the outer surface of the cup-like element 43a of the disc valve.

The portion I44 of intermediate diameter of stem I40 engages a flange I58a on the cover plate or housing I59 to thereby serve as a journal for the stem. Referring to Figure 19, housing I59 includes an arcuate slot I50 through which a set screw IBI extends to engage an arcuate strip I62, the end I63 of this strip serving as a stop against which the stop arm I56 will strike when the valve disc is in the extreme low position illustrated in Figure 25. Cover plate I59 is also provided with two outwardly extending depressions I64 arranged diametrically opposite and in which the lugs 89 of lock member 85 will engage when the valve disc element is in off position. A second pair'of depressions I55 are formed in the cover plate on a line extending at right angles to the line on which the depressions I64 are arranged. However, the depressions I65 difier from the depressions I64, in that one side edge of each depression' IE5 is inclined for a purpose.

A tongue I53a extends radially inwardly from the'peripheral wall of cover plate I59 at such point as to serve as a stop against which stop arm I 56 will contact when the valve disc element is in the fully closed position of Figure 23.

Figures 23 to 25 indicate the stages of operation of the valve structure of Figures 18 to 20, comprising the valve element 4Ia of Figures 20, 27 and 28 andthe valve body element I00 of Figures 29 to 31. Referring to Figure 23, valve element lla is there shown in closed position with its ports III and Ill! out of communication with the valve body element ports I54 and H35 and withthe port notches relatively positioned in the manner described above. Also, at this time, the stop arm I56 will be in engagement with the stop tongue I63a as is also shown in Figures 18 and 19.

By pressing the valve stem I40 inwardly to the position indicated in Figure 18, the lugs 89 of stop member 85 will be disengaged from the dethe housing 60.

pressions I64, so that the valve element may be rotated. This inward pressure upon the valve stem will, of course, contract the locking element spring 86 and also the spring element 65a, both as indicated in Figure 18. However, because of the fact that-the pockets 65b in which the ends of the arm 65a-seat are quite shallow, in fact, only about one quarter the depth of the corresponding pockets 49 of the Figure 1 structure, and also because the ends of the arms 65a are rounded as has been described in connection with the Figure 1 structure, the arms 65a will readily ride radially outwardly as the stem is pushed inwardly.

Rotation of the valve element in a clockwise direction with respect to Figures 19, 20 and 23 will move it to the full open position illustrated in Figure 24, wherein the ports of the valve element and valve body element are fully aligned. In finally reaching this position, the locking lugs 89 of lock member 85 will ridedown along the inclined edges I 66 of the depressions I65 and into these depressions so as to abut against the opposite and straight walls of the latter. The operator will thereby have an indication that-the valve is in full open position for ignition of the burner by the pilot device. In addition, the operator must again force the stem inwardly against the spring pressure before the valve can be turned to the Figure 25 low position. By this arrangement, the valve is certain to stay in a full open position for ignition of the burner before it can be turned to the low position of Figure 25.

Figure 25 illustrates the valv element Illa in the low or simmer position and with the stop arm I56 in contact with the surface I63 of the stop member I62. In this position, port III of the valve element has moved past supply port I04 and only receives gas from the latter through the notch Illa. Also, valve element port III] has moved entirely past delivery port I05 and gas only flows through the notch I051). The extreme low position can be adjusted by adjustment of the stop strip I62.

Referring to Figure 26, the valve structure there illustrated is particularly designed for use with oven burners, but includes a valve element 4Ia such as shown in use with the Figure 18 assembly, and which, valve element is illustrated in detail in Figures 20, 2'7 and 28. The Figure 26 assembly also includes the valve body element I00 used with the Figure 18 assembly and shown in detail in Figures 29 to 31.

In the Figure 26 assembly, the valve element IIa only moves between "off and full on positions and its stem M0, which is similar to that shown in Figures 21 and 22, carries a stop I55 shown in Figure 19a and including an arm I56. In off position of the valve, arm I56 will contact with a tongue I631) projecting inwardly from In full on position, such as shown in Figure 26. arm I56 will contact with a stop similar to I631), but positioned 90 around the housing.

A spring tsa is positioned between member I55 and the outer surface of valve element Ma to hold the latter seated.

The use in the valve element Maof ports III] and II I of sector-like or substantially triangular form permits of a maximum flow of gas in a valve element of minimum diameter. More particularly, if circular ports were provided in structures of the same diameter as those of Figures 18 and 26 and of such size as to give the same volume of flow as is obtained with the segmental ports III) when the valve element was in close position because points on the ports of the valve element would be too close to points on the ports of the valve body element.

It will, therefore, be understood that the present invention involving the provision of sectorlike ports further permits a maximum flow to be obtained with a gas valve of disc type having a size no greater thanthe usual plug type gas valve.

Figures 32 to 34 disclose a valve body element I20 intended for 'uSe with an oven valve and which includes a supply passage I2I extending radially thereof and a delivery passage I22 extending along a line parallel to the axis of the valve body element. Supply port I2I opens to the seat face I23 through a port I24 of segmental form, passage I2I being circular. Also, the supply passage I22 of circular form opens to a sector-like port I25 having its arcuate edge I26 of such length that its ends will coincide with the passage I22. The arcuate edge I2'I of port I24 is of such length that its ends will coincide with the diameter of supply passage I 2|. However, the edges I26 and I2'I both extend along a circular line concentric with the center point of the valve body element I20.

The oven valve illustrated in Figures 32 to 34 may be used with the sector-like ported valve element Illa of Figures 20, 27 and 28 or the circular port valve element 4| of Figures 1 to 17. However, as has been stated above, use of the Figure 20 valve element with the sector-like port valve body element of Figure 34 will permit a maximum flow with valve elements of minimum size. It will also be noted that the oven valve body of Figures 32 and 34 can be readily manufactured in a size similar to those of the top burner valves of Figures 1 to 25. This is highly desirable because of the present desire of manufacturers to have all valves upon a gas range of the same size. The present invention obtains this result and, in addition, enables similar valve elements, either such as 4| or Illa, to be used both on top burner valves and oven valves.

The use of sector-like ports in both the valve body element and the valve element'of an oven valve of hollow form is a distinct improvement because it permits the large iiow of gas necessary for an oven burner, usually 28,000 13. t. 11. per hour as compared with 12,000 E. t. u. for a top burner valve, to 'be obtained with a disc valve of small diameter. Disc type valves have numerous advantages. over the usual conical plug valves because their planar seat faces can be more easily and accurately machined. The present invention, involving the provision of a disc valve of the same diameter as the usual plug type valve, is highly important, particularly in gas range installations, though its advantages in other fields will be obvious.

Subject matter disclosed but not claimed herein may be claimed in my divisional application filed March 29, 1944, for Valve structures.

The terminology used in the specification is for the purpose of description and not of limitation, the scope of the invention being indicated in the claims.

I claim: 1. 'In a valve, a pair of plate members, at least one of said members having a peripheral flange ing upon the blank portion of the other plate member to brace such portion.

-2. In a valve, a pair of plate members, at least one of said members having a peripheral flange extending toward and secured to the other member, one of said members having ports therethrough adapted to be connected for flow by the space between the two members, the central portion of said ported member being blank, the other of said plate members having an aperture therein at its central portion, a socket element secured in the aperture and adapted to receive an operating stem, the inner end of the socket element bearing upon the blank portion of the other plate member to brace such portion.

3. A valve of the character described in claim 1 wherein each of the flow ports is of sectorlike form and is defined by an outer arcuate edge substantially concentric with the axis of the valve and two straight side edges which join each other at a point between the valve axis and the outer arcuate edge of the port.

4. A valve of the character described in claim 2 wherein each of the flow ports is of sector-like form and is defined by an outer arcuate edge substantially concentric with the axis of the valve and two straight side edges which join each other at a point between the valve axis and the outer arcuate edge of the port. I WILLIAM ROBINSON. 

